English

Sharp-interface approach for simulating solid-state dewetting in two dimensions: a Cahn-Hoffman $\boldsymbol{\xi}$-vector formulation

Soft Condensed Matter 2019-03-27 v2 Materials Science Computational Physics

Abstract

By using a Cahn-Hoffman ξ\boldsymbol{\xi}-vector formulation, we propose a sharp-interface approach for solving solid-state dewetting problems in two dimensions. First, based on the thermodynamic variation and smooth vector-field perturbation method, we rigorously derive a sharp-interface model with weakly anisotropic surface energies, and this model describes the interface evolution which occurs through surface diffusion flow and contact line migration. Second, a parametric finite element method in terms of the ξ\boldsymbol{\xi}-vector formulation is proposed for numerically solving the sharp-interface model. By performing numerical simulations, we examine several specific evolution processes for solid-state dewetting of thin films, e.g., the evolution of small islands, pinch-off of large islands and power-law retraction dynamics of semi-infinite step films, and these simulation results are highly consistent with experimental observations. Finally, we also include the strong surface energy anisotropy into the sharp-interface model and design its corresponding numerical scheme via the ξ\boldsymbol{\xi}-vector formulation.

Keywords

Cite

@article{arxiv.1804.00270,
  title  = {Sharp-interface approach for simulating solid-state dewetting in two dimensions: a Cahn-Hoffman $\boldsymbol{\xi}$-vector formulation},
  author = {Wei Jiang and Quan Zhao},
  journal= {arXiv preprint arXiv:1804.00270},
  year   = {2019}
}
R2 v1 2026-06-23T01:10:43.828Z